JP2011166490A - Imaging device and power supply control method of imaging device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an imaging device and a power supply control method of the imaging device, wherein a camera can turn off power supply not by an external device but by the camera itself, so as to reduce the load of a battery, while reducing the weight of a vehicle by shortening a cable length. <P>SOLUTION: An imaging device is equipped with: an imaging element 118 for receiving light from a subject and converting the light to an electric signal; a video signal processing circuit 116 for performing signal processing on a video signal generated based on the electric signal; a power supply circuit 114 for supplying power to the video processing circuit; a signal detection unit 112 for receiving a back lamp signal indicating light-on or light-off of a back lamp from a back lamp 70 installed at a back part of a vehicle; and a power supply control unit 112 for controlling the power supply circuit based on the back lamp signal so that the power supply is turned ON in time of light-on of the back lamp, the power supply is turned ON for a preset time after the light-off of the back lamp, and the power supply is turned OFF after the preset time has elapsed. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an imaging apparatus and a power control method for the imaging apparatus.

  There is a camera system in which a back camera (Backup Camera) that captures the back of the car is installed at the rear of the car, and a driver can check the back of the car on a screen installed in the car. Images taken by the rear camera are displayed on the display of the car navigation device or the display installed at the position of the rearview mirror when the automobile is moving backward.

  The example shown in FIG. 7 is a camera system 1 in which a camera 50 that captures the rear of an automobile is connected to the car navigation device 20. FIG. 7 is a block diagram showing a conventional camera system 1. The camera 50 includes a camera power supply circuit 54, a video signal processing circuit (DSP) 56, a CCD image sensor 58, a video driver 59, and the like. The car navigation device 20 includes a control unit 22 and a display 24. In the camera system 1, the rear gear detection unit 12 detects the state of the gear 10 and outputs a rear gear on signal indicating whether or not the gear 10 is in the rear state, and the control unit 22 of the car navigation device 20 is based on the rear gear on signal. Thus, the power on / off of the camera 50 is controlled. At the same time, the control unit 22 of the car navigation device 20 controls display or non-display of the display 24.

  The example shown in FIG. 8 is a camera system 2 in which a vehicle does not have a car navigation device and a camera 50 and a display 40 are connected. FIG. 8 is a block diagram showing a conventional camera system 2. In the camera system 2, the camera 50 is connected to the battery 30 and is always energized. The display or non-display of the display 40 is controlled by the display 40 detecting the gear state of the vehicle based on the rear gear on signal.

  Patent Document 1 discloses that a display device detects a signal such as a rear gear or a backup lamp and switches the display of a video from a camera and other external video.

  In Patent Document 2, as shown in FIG. 9, the camera 50 includes a power supply control unit 52 (= relay circuit), a camera power supply circuit 54, a video signal processing circuit 56, a CCD image sensor 58, and the like. 3 is disclosed. FIG. 9 is a block diagram showing a conventional camera system 3. The camera power supply circuit 54 supplies driving power to the camera 50 in response to an input of a rear gear on signal. The camera 50 and the display 40 are connected by a connection cable that transmits a video signal.

JP-A-11-55656 JP-A-7-236134

  In the example shown in FIG. 7, the power on / off control of the camera 50 depends on the car navigation device 20, and the camera 50 does not have a function related to the power on / off control of the camera 50 itself. Therefore, in order to perform the power on / off control of the camera 50, the car navigation device 20 needs to have a function related to the power on / off control of the camera 50.

  In the example shown in FIG. 8, since the camera 50 is always energized, the load on the battery 30 due to current consumption cannot be eliminated. Further, the internal temperature rises due to the heat generated by the camera 50 itself. Furthermore, since it is not necessary to display an image behind the automobile and the camera 50 is energized even though it is not used as an imaging device, the energization time increases and the product life is affected.

  In Cited Document 2, the power supply for driving the camera 50 is based on the input of a rear gear on signal. However, in order to input the rear gear-on signal to the camera 50, it is necessary to route a signal cable from the gear 10 to the camera 50 installed at the rear of the automobile, and there is a problem that the cable length becomes long.

  Therefore, the present invention has been made in view of the above problems, and an object of the present invention is to reduce the cable length and reduce the weight of the vehicle, while the camera itself is not an external device but the camera itself. It is an object of the present invention to provide a new and improved imaging apparatus and imaging apparatus power control method capable of performing power on / off control and reducing a load on a battery.

  In order to solve the above problems, according to an aspect of the present invention, an image sensor that receives light from a subject and converts the light into an electrical signal, and an image that performs signal processing on a video signal generated based on the electrical signal A signal processing circuit; a power supply circuit that supplies power to the video signal processing circuit; a signal detection unit that receives a back lamp signal indicating whether the back lamp is turned on or off from a back lamp installed at the rear of the vehicle; The power supply is turned on when the back lamp is turned on, the power supply is turned on for a preset time after the back lamp is turned off, and the power supply is turned off after the preset time has elapsed. Thus, an imaging apparatus including a power supply control unit that controls a power supply circuit is provided.

  Based on the back lamp signal, the elapsed time after the back lamp is extinguished is measured, and further includes a timer that outputs a time elapsed signal indicating that a preset time has elapsed to the power source control unit, the power source control unit, The power supply circuit may be controlled based on the time lapse signal.

The timer may be provided in the video signal processing circuit.
In the timer, a time for turning on the power supply after the back lamp is turned off may be set.

  The power supply circuit is arranged connected to an external battery, and turns on the output voltage when power supply is turned on, and turns off the output voltage when power supply is turned off.

  In order to solve the above problem, according to another aspect of the present invention, the signal detection unit receives a back lamp signal indicating whether the back lamp is turned on or off from a back lamp installed at the rear of the vehicle. A power supply circuit for a video signal processing circuit that processes a video signal generated based on an electrical signal converted by receiving light from a subject when the back lamp is turned on based on the back lamp signal Turning on the power supply, turning on the power supply to the video signal processing circuit for a preset time after the back lamp is turned off, and setting the power supply circuit in advance. And a step of turning off the supply of power to the video signal processing circuit after the elapsed time has elapsed.

  As described above, according to the present invention, while reducing the cable length and reducing the weight of the vehicle, the camera itself can control the power on / off of the camera, not the external device, thereby reducing the load on the battery. be able to.

1 is an external view showing a rear portion of an automobile 100. FIG. 1 is a block diagram showing a camera 110 and a camera system including the camera 110 according to an embodiment of the present invention. 2 is a block diagram showing a power control unit 112 of the camera 110 according to the embodiment. FIG. 3 is a circuit diagram illustrating a circuit example of a power control unit 112 of the camera 110 according to the embodiment. FIG. 5 is a flowchart showing an operation related to power on / off control of the camera 110 according to the embodiment. 6 is a timing chart showing an operation related to power on / off control of the camera 110 according to the embodiment. It is a block diagram which shows the conventional camera system. It is a block diagram which shows the conventional camera system. It is a block diagram which shows the conventional camera system 3. It is a block diagram which shows the conventional camera system.

  Exemplary embodiments of the present invention will be described below in detail with reference to the accompanying drawings. In addition, in this specification and drawing, about the component which has the substantially same function structure, duplication description is abbreviate | omitted by attaching | subjecting the same code | symbol.

The description will be made in the following order.
1. Configuration of one embodiment Operation of one embodiment

<1. Configuration of one embodiment>
[External appearance of camera 110]
First, an example of the appearance of a camera 110 according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is an external view showing a rear portion of the automobile 100.

  As shown in FIG. 1, a camera 110 and a back lamp 70 are provided at the rear of the automobile 100.

  The camera 110 is a back camera (Backup Camera or Rear View Camera) and photographs the back of the automobile 100. The image captured by the camera 110 is displayed on a display installed in the vehicle when the vehicle 100 moves backward, and provides a subject image behind the vehicle 100 to the driver to support backward driving.

  The back lamp 70 (Reversing lamp or Backup light) emits light behind the automobile 100 when the automobile 100 moves backward, and the automobile 100 moves backward to other drivers or pedestrians behind the automobile 100. Let them know.

  The camera 110 and the back lamp 70 are connected by a signal cable that sends a signal indicating whether the back lamp 70 is turned on or off to the camera 110. Since the camera 110 and the back lamp 70 are both installed at the rear of the automobile 100, the cable connecting the camera 110 and the back lamp 70 may be shorter than the signal cable connecting the camera 110 and the gear.

[Configuration of Camera 110]
Next, the configuration of the camera 110 according to the present embodiment and the camera system including the camera 110 will be described with reference to FIG. FIG. 2 is a block diagram illustrating the camera 110 and the camera system including the camera 110 according to the present embodiment.

  As shown in FIG. 2, the automobile 100 includes a gear 10, a rear gear detection unit 12, a back lamp 70, a noise filter 72, a display 40, and a camera 110, and configures a camera system.

  The rear gear detection unit 12 detects that the gear 10 has been switched from a state other than the rear to the rear (reverse), or that the gear 10 has been switched from the rear state to other than the rear. The rear gear detection unit 12 outputs a rear gear signal indicating the rear state of the gear 10 according to the state of the gear 10.

  The back lamp 70 receives a rear gear signal from the rear gear detection unit 12 and is turned on when the gear 10 is in the rear state, and is turned off when the gear 10 is in a state other than the rear. Further, the back lamp 70 outputs a back lamp signal indicating whether the back lamp 70 is turned on or off. The back lamp signal is output to the camera 110 via the noise filter 72. The noise filter 72 prevents noise from entering the back lamp signal or leaking outside.

  The battery 30 is a power source mounted on the automobile 100 and supplies electric power to each component of the automobile that requires electric power, such as the camera 110. In the present embodiment, the battery 30 and the camera 110 are directly connected without going through an external device such as the display 40 or the car navigation device, and power is directly supplied from the battery 30 to the camera 110. Accordingly, the camera 110 itself can control the power on / off of the camera 110, and an external device such as the display 40 or the car navigation device does not need to control the power on / off of the camera 110.

  The display 40 receives a video signal from the camera 110 and displays a subject image captured by the camera 110. With the camera 110 powered on, the camera 110 outputs a video signal to the display 40, and the display 40 displays the video from the camera 110. On the other hand, when the camera 110 is turned off, the camera 110 does not output a video signal, so the display 40 does not display the video from the camera 110. Thus, the display or non-display of the video from the camera 110 on the display 40 is controlled by turning on and off the power of the camera 110.

  As shown in FIG. 2, the camera 110 includes, for example, a power control unit 112, a camera power circuit 114, a video signal processing circuit 116, a CCD image sensor 118, a video driver 122, and the like.

  The power control unit 112 controls the camera power circuit 114 based on the back lamp signal. The power supply control unit 112 controls the camera power supply circuit 114 to turn on the supply of power when the back lamp 70 is lit. Further, the power supply control unit 112 turns on the power supply for a preset time after the back lamp 70 is turned off, and turns off the power supply after the preset time has elapsed. To control. The preset time is, for example, a period of several seconds to several tens of seconds.

  The camera power supply circuit 114 is connected to the battery 30 and supplies power to each component of the camera 110 such as the video signal processing circuit 116. The power supply by the camera power supply circuit 114 is turned on / off based on the control of the power supply control unit 112. The camera power supply circuit 114 is arranged connected to the external battery 30. The camera power supply circuit 114 turns on the camera power supply circuit 114 when power supply is necessary and power supply is turned on, and turns off the camera power supply circuit 114 when power supply is turned off without power supply. The camera power supply circuit 114 outputs a voltage from the camera power supply circuit 114 when turned on, and does not output a voltage from the camera power supply circuit 114 when turned off. In the present embodiment, the battery power supply circuit 114 is not connected or disconnected between the battery 30 and the camera power supply circuit 114, but the camera power supply circuit 114 is controlled to turn on / off the voltage output.

  The video signal processing circuit 116 performs various types of signal processing on the video signal based on the electrical signal generated by the CCD image sensor 118. For the signal processing in the video signal processing circuit 116, a normal technique can be applied, and detailed description thereof is omitted in this specification. The video signal processing circuit 116 is a microcomputer, for example, and has a timer 117. The timer 117 measures the elapsed time after the back lamp 70 is extinguished based on the back lamp signal, and outputs a time elapsed signal indicating that a preset time has elapsed to the power supply control unit 112. In the timer 117, a time for turning on the power supply after the back lamp 70 is turned off is set.

  The CCD image sensor 118 is an example of an image sensor, receives light from a subject, and converts the light received from the subject into an electrical signal. Then, the CCD image sensor 118 outputs the generated electric signal to the video signal processing circuit 116 or the like.

  The video driver 122 receives the video signal from the video signal processing circuit 116 and generates a display signal for displaying the video on the display 40. The video driver 122 outputs the generated display signal to the display 40.

[Power control unit 112]
Next, the power control unit 112 of the camera 110 according to the present embodiment will be described with reference to FIG. FIG. 3 is a block diagram showing the power control unit 112 of the camera 110 according to the present embodiment.

  The power supply control unit 112 includes, for example, a power supply circuit control signal detection circuit 132, a NOR circuit 134, a power supply circuit control circuit 136, a timer start timing detection circuit 138, and the like.

  The power supply circuit control signal detection circuit 132 receives the back lamp signal and detects whether the back lamp 70 is on or the back lamp 70 is off. The power supply circuit control signal detection circuit 132 outputs the detection result to the NOR circuit 134. The power supply circuit control signal detection circuit 132 outputs True when the back lamp 70 is on, and outputs False when the back lamp 70 is off.

  The timer start timing detection circuit 138 is an example of a signal detection unit, receives a back lamp signal, and detects whether the back lamp 70 is on or the back lamp 70 is off. The timer start timing detection circuit 138 outputs a start signal to the video signal processing circuit 116 when the back lamp 70 is turned off. Based on the start signal output from the timer start timing detection circuit 138, the timer 117 of the video signal processing circuit 116 starts measuring elapsed time.

  The timer 117 of the video signal processing circuit 116 outputs True when the back lamp 70 is turned on and the elapsed time measurement is stopped. The timer 117 starts measuring elapsed time, outputs True before a preset time elapses, and outputs False after a preset time elapses.

  The NOR circuit 134 is a circuit that realizes negation of a logical sum. The NOR circuit 134 outputs True only when the two inputs are False. A signal from the power circuit control signal detection circuit 132 and a signal from the video signal processing circuit 116 are input to the NOR circuit 134.

  When the back lamp 70 is on and the timer 117 is stopped, True is input from the power supply circuit control signal detection circuit 132, and True is also input from the timer 117. Therefore, the NOR circuit 134 outputs False. . Since the back lamp 70 is turned off, the measurement of the timer 117 is started, and before a preset time elapses, False is output from the power supply circuit control signal detection circuit 132, and True is input from the timer 117. The circuit 134 outputs False. After the back lamp 70 is turned off and the measurement of the timer 117 is started and a preset time has elapsed, False is output from the power supply circuit control signal detection circuit 132, and False is input from the timer 117. The circuit 134 outputs True.

  The power supply circuit control circuit 136 receives the signal from the NOR circuit 134 and generates a control signal for turning on the power supply by the camera power supply circuit 114 and a control signal for turning off the power supply by the camera power supply circuit 114. .

  When the back lamp 70 is on and the timer 117 is stopped, and before the back lamp 70 is turned off and the measurement of the timer 117 starts and a preset time elapses, the power supply circuit control circuit 136 False is received from the NOR circuit 134. Therefore, the power supply circuit control circuit 136 generates a control signal for turning on the supply of power. After the back lamp 70 is turned off and the measurement of the timer 117 is started and a preset time has elapsed, the power supply circuit control circuit 136 receives True from the NOR circuit 134. Therefore, the power supply circuit control circuit 136 generates a control signal for turning off the supply of power. The power supply circuit control circuit 136 outputs a control signal to the camera power supply circuit 114.

[Circuit example of camera 110]
Next, a circuit example of the power control unit 112 of the camera 110 according to the present embodiment will be described with reference to FIG. FIG. 4 is a circuit diagram illustrating a circuit example of the power control unit 112 of the camera 110 according to the present embodiment.

  The camera power supply circuit 114 and the video signal processing circuit 116 are, for example, ICs (integrated circuits). The camera power supply circuit 114 has, for example, an INPUT terminal, an OUTPUT terminal, an Enable terminal, and a GND terminal. The video signal processing circuit 116 has, for example, a Vcc terminal, a GND terminal, an INPUT terminal, and an OUTPUT terminal.

  The power controller 112 includes resistors R503, R504, R505, R506, R507, R508, R509, a capacitor C502, digital transistors Q502, Q503, Q504, Q505, and the like.

  In the camera power circuit 114, the INPUT terminal is connected to the power input from the battery 30. The OUTPUT terminal is connected to the Vcc terminal of the video signal processing circuit 116 and the output terminal of the resistor R507. The Enable terminal is connected between the input terminal of the resistor R504, the output terminal of the resistor R503, and the collector terminal of the digital transistor Q502. The GND terminal is GND-connected.

  In the video signal processing circuit 116, the Vcc terminal is connected to the OUTPUT terminal of the camera power supply circuit 114. The GND terminal is GND-connected. The INPUT terminal is connected between the input terminal of the resistor R507 and the collector terminal of the digital transistor Q505. The OUTPUT terminal is connected to the input terminal of the resistor R506 and the base terminal of the digital transistor Q503.

  In the power supply control unit 112, the resistor R503 has an input terminal connected to the power supply input from the battery 30, and an output terminal connected to the input terminal of the resistor R504 and the collector terminal of the digital transistor Q502. The resistor R504 has an input terminal connected to the Enable terminal of the camera power supply circuit 114 and an output terminal connected to GND. The resistor R505 has an input terminal connected to the power supply input from the battery 30, and an output terminal connected to the base terminal of the digital transistor Q502, the collector terminal of the digital transistor Q503, and the collector terminal of the digital transistor Q504. The resistor R506 has an input terminal connected to the OUTPUT terminal of the video signal processing circuit 116 and the base terminal of the digital transistor Q503, and an output terminal connected to GND.

  The resistor R507 has an input terminal connected to the INPUT terminal of the video signal processing circuit 116 and an output terminal connected to the OUTPUT terminal of the camera power supply circuit 114. The resistor R508 has an input terminal connected between the output terminal of the resistor R509 and the base terminal of the digital transistor Q504, the base terminal of the digital transistor Q505, and the input terminal of the capacitor C502, and the output terminal is GND-connected. The resistor R509 has an input terminal connected to the input of the back ramp signal, and an output terminal connected to the input terminal of the resistor R508, the base terminal of the digital transistor Q504, the base terminal of the digital transistor Q505, and the input terminal of the capacitor C502. Capacitor C502 has an input end connected to the output end of resistor R509, and an output end connected to GND.

  The digital transistor Q502 has a base terminal connected to the output terminal of the resistor R505, a collector terminal connected between the output terminal of the resistor R503, the Enable terminal of the camera power supply circuit 114, and the input terminal of the resistor R504. The base terminal of the digital transistor Q503 is connected to the OUTPUT terminal of the video signal processing circuit 116 and the input terminal of the resistor R506, the collector terminal is the output terminal of the resistor R505, the base terminal of the digital transistor Q502, and the collector terminal of the digital transistor Q504. Connected to. The digital transistor Q504 has a base terminal connected to the output terminal of the resistor R509, and a collector terminal connected to the output terminal of the resistor R505, the base terminal of the digital transistor Q502, and the collector terminal of the digital transistor Q503. The digital transistor Q505 has a base terminal connected to the output terminal of the resistor R509, a collector terminal connected to the input terminal of the resistor R507, and the INPUT terminal of the video signal processing circuit 116. The emitter terminals of the digital transistors Q502, Q503, Q504, and Q505 are all GND connected.

<2. Operation of one embodiment>
Next, the operation of the camera 110 will be described with reference to FIGS. FIG. 5 is a flowchart showing an operation related to power on / off control of the camera 110 according to the present embodiment. FIG. 6 is a timing chart showing an operation related to power on / off control of the camera 110 according to the present embodiment. In FIG. 6, “−B” in the digital transistor Q indicates a base terminal, and “−C” indicates a collector terminal. In FIG. 6, “DSP” indicates the video signal processing circuit 116, and “IC 502” indicates the camera power supply circuit 114.

  First, the cell start of the battery 30 will be described. When the cell starts, the voltage of the battery 30 is applied to the camera 110 (step S1). At this time, the digital transistor Q502 is turned on (step S2). Digital transistors Q503 and Q504 are off. Then, Enable of the camera power supply circuit 114 becomes Low, and the output voltage of the camera power supply circuit 114 is turned off (step S3).

  Next, the camera 110 detects the state of the back lamp 70 (step S4), and continues to detect the state of the back lamp 70 while the back lamp 70 is turned off. On the other hand, when the lighting of the back lamp 70 is detected, the digital transistor Q504 is turned on (step S5). At this time, the digital transistor Q505 is not operating. Then, the digital transistor Q502 is turned off (step S6). Subsequently, Enable of the camera power supply circuit 114 becomes High, and the output voltage of the camera power supply circuit 114 is turned on (step S7). As a result, the power supply voltage (Vcc) is applied to each component of the camera 110 to supply power.

  Next, the video signal processing circuit 116 starts operating, and the camera 110 starts driving. At the same time as the power supply voltage (Vcc) is applied, the digital transistor Q505 is turned on (ON) (step S8). As a result, the INPUT terminal of the video signal processing circuit 116 remains in the Low state, and the video signal processing circuit 116 detects this state and sets the OUTPUT terminal to High (step S9). Thereby, the digital transistor Q503 is turned on (step S10).

  The camera 110 detects the state of the back lamp 70 (step S11), and continues to detect the state of the back lamp 70 while the back lamp 70 is lit. On the other hand, when the turn-off of the back lamp 70 is detected, the digital transistors Q504 and Q505 are turned off (step S12). At this time, since the digital transistor Q503 is on, Enable of the camera power supply circuit 114 remains in a high state, and the camera power supply circuit 114 continues to supply power.

  When the digital transistor Q505 is turned off, the INPUT terminal of the video signal processing circuit 116 becomes High, and the timer 117 incorporated in the video signal processing circuit 116 starts measuring elapsed time (step S13). The timer 117 checks whether or not a preset time has elapsed (step S14). Step S14 is repeated until a preset time has elapsed.

  On the other hand, after the preset time has elapsed, the OUTPUT terminal of the video signal processing circuit 116 is set to Low (step S15), and the digital transistor Q503 is turned off (step S16). Then, the digital transistor Q502 is turned on (step S17). Subsequently, Enable of the camera power supply circuit 114 becomes Low, and the output voltage of the camera power supply circuit 114 is turned off (step S17). As a result, the power supply voltage (Vcc) applied to each component of the camera 110 is turned off, and the supply of power is stopped.

  As described above, in the present embodiment, the power source built in the camera 110 can be turned on / off by combining the circuit of the camera 110 that detects whether the back lamp 70 is turned on or off and the function of the microcomputer of the video signal processing circuit (DSP) 116. Functions can be realized. When the back lamp 70 is lit, the camera 110 turns on its own power, and as a result, a video signal is output and an image is displayed on the display 40. When the back lamp 70 is turned off, the camera 110 turns off its power supply after a set time has elapsed. After the back lamp 70 is turned off, for example, the camera 110 is operated for several seconds to several tens of seconds, and an image is displayed on the display 40, so that the driver can continue for a while after stopping the backward movement of the automobile 100. The back of the automobile 100 can be confirmed from the video taken by the camera 110. The time until the camera 110 is turned off after the back lamp 70 is turned off can be freely set by, for example, a timer 117 built in the microcomputer of the video signal processing circuit (DSP) 116.

  According to this embodiment, only the power control unit 112 of the camera 110 is always energized, and the camera power circuit 114 is not energized constantly unlike the conventional example shown in FIG. As a result, energy saving can be achieved, and the burden on the battery 30 can be reduced. In addition, since the energization time is shortened, the life of the camera 110 itself is extended. Furthermore, since the temperature rise inside the camera 110 can be suppressed, the reliability of the camera 110 can be improved.

  Furthermore, the camera system including the camera 110 and the camera 110 described above does not require an external device such as a car navigation device. The camera 110 is also installed in a car not equipped with the car navigation device, and the camera 110 is turned on / off. Control can be easily performed.

  Further, in the present embodiment, in consideration of the wiring of the signal cable in the automobile 100, the power of the camera 110 is turned on / off using a signal from the back lamp 70 as a trigger. That is, in this embodiment, the cable length of the signal cable can be shortened as compared with the case where the rear gear of the gear is detected and the power of the camera is turned on / off.

  Furthermore, the power of the camera 110 of this embodiment is directly supplied from, for example, the battery 30 without being shared with the back lamp 70. FIG. 10 shows the camera system 4 in the case where the power supply of the back lamp 70 and the camera 110 is shared unlike the present embodiment. FIG. 10 is a block diagram showing a conventional camera system 4.

  In the camera system 4, the control unit 60 performs on / off control of the back lamp 70 and on / off control of the power supply of the camera 50 based on the rear gear on signal. In the example shown in FIG. 10, the camera 50 may affect the lighting / non-lighting control of the back lamp 70, and there is a problem in ensuring safety. On the other hand, in this embodiment, since the power of the camera 110 is directly supplied from the battery 30 without being shared with the back lamp 70, a safety problem can be avoided.

  In the example illustrated in FIG. 10, the on / off of the back lamp 70 and the on / off of the camera 50 are controlled simultaneously. Therefore, as in the present embodiment, it is impossible to control to turn off the camera 50 after the preset time has elapsed after the back lamp 70 is turned off. On the other hand, according to the present embodiment, the on / off of the camera 110 can be controlled independently of the on / off of the back lamp 70.

  The preferred embodiments of the present invention have been described in detail above with reference to the accompanying drawings, but the present invention is not limited to such examples. It is obvious that a person having ordinary knowledge in the technical field to which the present invention pertains can come up with various changes or modifications within the scope of the technical idea described in the claims. Of course, it is understood that these also belong to the technical scope of the present invention.

1, 2, 3, 4 Camera system 10 Gear 12 Rear gear detector 20 Car navigation device 22, 60 Controller 24, 40 Display 30 Battery 50, 110 Camera 52, 112 Power controller 54, 114 Camera power circuit 56, 116 Video Signal processing circuit 58, 118 CCD image sensor 59, 122 Video driver 70 Back lamp 72 Noise filter 100 Automobile 117 Timer 132 Power supply circuit control signal detection circuit 134 NOR circuit 136 Power supply circuit control circuit 138 Timer start timing detection circuit R503, R504, R505, R506, R507, R508, R509 Resistor C502 Capacitor Q502, Q503, Q504, Q505 Digital transistor

Claims (6)

An image sensor that receives light from a subject and converts the light into an electrical signal;
A video signal processing circuit for signal processing a video signal generated based on the electrical signal;
A power supply circuit for supplying power to the video signal processing circuit;
A signal detection unit that receives a back lamp signal indicating lighting or extinguishing of the back lamp from a back lamp installed at the rear of the vehicle;
Based on the back lamp signal, the power supply is turned on when the back lamp is turned on, and the power supply is turned on for a preset time after the back lamp is extinguished, and the preset time is turned on. An imaging apparatus comprising: a power supply control unit that controls the power supply circuit so as to turn off the supply of the power after a lapse of time. Further comprising a timer for measuring an elapsed time after the back lamp is turned off based on the back lamp signal, and outputting a time lapse signal indicating that the preset time has elapsed to the power control unit;
The imaging device according to claim 1, wherein the power supply control unit controls the power supply circuit based on the time lapse signal.   The imaging device according to claim 2, wherein the timer is provided in the video signal processing circuit.   The imaging apparatus according to claim 2, wherein a time for turning on the supply of power after the back lamp is turned off is set in the timer.   The power supply circuit is arranged connected to an external battery, and turns on an output voltage when the power supply is turned on, and turns off an output voltage when the power supply is turned off. The imaging device according to any one of the above. A step of receiving a back lamp signal indicating that the back lamp is turned on or off from a back lamp installed at the rear of the vehicle;
Based on the back lamp signal, when the back lamp is turned on, a power supply for a video signal processing circuit that performs signal processing on a video signal generated based on an electrical signal that the image sensor receives and converts light from a subject. The circuit turning on the power supply;
The power supply circuit turns on the supply of power to the video signal processing circuit for a preset time after the backlight is turned off;
And a step of turning off the supply of power to the video signal processing circuit after the preset time has elapsed.

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